DE1441153B1 - Circuit arrangement for a compatible stereo decoder for use in an FM receiver for optional reception of monophonic or stereophonic broadcasts - Google Patents

Description

The invention relates to a circuit arrangement for a compatible stereo decoder in an FM receiver equipped with a ratio detector for receiving signals that differ according to the pilot tone method from one with the sum of the right and left AF signals directly modulated carrier wave, from an amplitude-modulated with the difference of the right and left AF signals Subcarrier with suppressed carrier wave, and one with the frequency of the subcarrier Assemble the pilot tone kept synchronized, with a stage for the recovery of the suppressed Subcarrier.

They are compatible transmission systems for frequency modulated using time division multiplex technology Mono and stereo broadcasts known (cf. the magazine "Electronic Engineering", April 1960, p. 238 / 239), in which the frequency-modulated multiplex signal picked up by the receiver from a with the Sum of the right and left AF signals directly modulated carrier wave and one with the difference of these signals consists of amplitude-modulated subcarriers with suppressed carrier waves, while a synchronizing signal transmitted from the subcarrier frequency (sampling frequency) at the Subject of the invention used pilot tone kept synchronized with the frequency of the subcarrier and also a component amplitude-modulated with the sum of the LF signals in Form of the second harmonic of the subcarrier is part of the multiplex signal. Also has the Receiver of this known arrangement already has a regeneration stage in the form of a phase-synchronized one Oscillator for the suppressed subcarrier and a synchronous detector with two in push-pull controlled channels. These stages, known as synchronizing separators and decoders, lead out the demodulated FM multiplex signal appearing at the output of the ratio detector the right and the left NF signal immediately.

It is also known in principle that the component amplitude-modulated with the sum of the LF signals the subcarrier frequency, d. H. the component corresponding to its second harmonic To omit broadcasting systems of the genus of the subject of the invention in the multiplex signal (cf. the journal "IEE Convention Record", Part. 7, 1960, pp. 128 to 144), with no regard to it it must be taken whether in the stereo decoder the demodulated LF signals directly from the synchronous detector broken down or broken down via a matrix network connected to its output be routed into the NF channels assigned to them.

The object of the invention, on the other hand, is to provide stereo decoder circuits without a signal at the output of the stereo code modulator or synchronous modulator connected matrix network for deriving the demodulated LF signals get along in separate audio channels.

This is achieved according to the invention in that a synchronous detector with a center-tapped Transmitter is provided for the subcarrier, on the output side of which the subcarrier occurs in push-pull mode, that the center tap of the output side of the transformer with one of the demodulated LF signals leading output of the ratio detector is connected to the two ends of the center-tapped winding of the transformer via time constant elements and two diodes connected in series in the same direction each connected to the other end of the center-tapped winding that of the Connection point of two diodes each has a charging capacitor connected to ground, to which each a channel signal arises that the two diode circuits are connected to the transformer with opposite polarity and that the time constant of the time constant members is large compared to the period of the subcarrier.

The differences of the object of the invention over the known are that the Stereo modulation takes place through diode circuits fed via time constant elements in demodulation channels, which are supplied via a center-tapped transformer with the auxiliary carrier in push-pull mode, that even with stereophonic broadcast systems, corresponding matrix networks are dispensed with can.

The subject matter of the invention is also inventive because it is not limited to the knowledge that when decoding transmitted according to the pilot tone method and composed accordingly Multiplex signals can do without a matrix network even if the Multiplex signal no component modulated with the sum of the LF signals in the form of the second harmonic of the subcarrier. This requires a special design of the synchronous detector circuit, in order to use them instead of one of the synchronous detectors known for pilot tone methods.

The progress that can be achieved by the subject matter of the invention is the saving of one Matrix network in systems that work according to the same pilot tone method, on the other hand the stereophonic radio systems in that when designing the bandwidth of the transmission path or the receiver to an additional Component of double subcarrier frequency is not to be taken into account.

According to what is known, the overall signal can also be viewed as a carrier in the subject matter of the invention frequency modulated according to the following modulation function:

M (O = K ₁ (A + B) + K ₁ (AB) S + KS, (1)

where A and B mean the left and right NF signals. Accordingly, the first term of the equation is the sum of these two signals. Since this transmission method is a direct modulation of the carrier with the sum of the right and left LF signals, the method is compatible, ie even an FM receiver suitable only for monophonic reproduction can process this component of the overall stereophonic signal and accordingly deliver a monaural reproduction.

The second term of the equation represents a modulation component that is modulated by an amplitude Subcarrier is formed with suppressed carrier wave and the difference information leads, d. H. is amplitude-modulated with the difference between the right and left AF signals.

Since this difference information is carried by means of an auxiliary carrier with a suppressed carrier wave, the total stereophonic signal must also contain a pilot signal that is at the frequency of the suppressed Auxiliary carrier is kept synchronized and in the receiver to regenerate the suppressed carrier

gers serves. This pilot signal is through the third Term of the equation shown.

K ₁ and K ₂ represent constant quantities.

Known as the Püotton- or time-division multiplex method and briefly explained transmission principle is by the American federal law enforcement agency (FCC) has been declared binding, so that the circuit arrangement according to the invention described is adapted to this transmission method.

An embodiment according to the invention will now be explained in more detail with reference to the drawing; in this shows

Fig. 1 is a block diagram of a receiver with the stereo decoder according to the invention and

Fig. 2 is a family of curves used to explain the Operation of the stereo decoder according to the invention is used.

As Fig. 1 shows, the receiver can after Invention used to record monophonic and stereophonic frequency-modulated broadcasts and adjusts itself between these two modes according to the character of the received Signal automatically.

In the receiver according to FIG. 1, the input stages are designed in the usual way. This includes sen a single or multi-stage RF amplifier, a mixer and a ratio detector. The entrance of the RF amplifier 10 is connected to a receiving antenna 11, while the output is to module 12 is connected to a number of IF amplifiers and one or more amplitude limiters contains. Sensitive input elements are used for the circuit according to the invention, so that the signal-to-noise ratio, especially in stereo operation in the peripheral coverage areas of the relevant Sender receives an acceptable value. It is also desirable to have both an automatic Gain control for the HF and IF stages, as well as an automatic frequency correction of the mixer oscillator. The IF bandwidth of a standard FM receiver for monaural operation is between 150 and 180 kHz at 6 db. The IF bandwidth of an FM receiver for monaural and stereophonic operation should be wider to avoid cross-modulations or crosstalk in one information contained in a single shipment. According to the guidelines of the American The Federal News Agency can also broadcast a second secondary carrier to the To enable stereophonic or monophonic radio broadcasts with practically no mutual interference. An IF bandwidth of the receiver of 230 kHz is sufficient if the automatic gain control the level of the signal through the RF and IF amplifiers despite changes in the strength of the received Signal at a practically constant value.

The intermediate frequency and limiter stage 12 is followed by a ratio detector 13 that responds to the amplitude limited intermediate frequency signal responds to. generate a composite or multiplex signal, which corresponds to the modulation function of the received carrier wave.

The ratio detector is followed by a synchronous detector with a pair of push-pull channels in order to derive the right and left LF signals or A or B signals directly from the multiplex signal which is available at the output of the ratio detector. These two channels have the same structure, so that only one needs to be described here. The Λΐ channel is therefore explained in more detail below. The corresponding components of the .B channel have the same reference numerals, which are, however, identified with the index b instead of the index α. The reference numbers that are common to both channels do not have an index.

The stereo decoder has a stage 40 for regenerating the suppressed subcarrier from the pilot tone, which is a frequency doubler for the pilot frequency or just an input coupling circuit to which a corresponding external signal source is coupled is, can be. Such a coupling circuit is shown in the drawing, the coupling into the channels via the secondary side of a double-tuned band filter 20. This secondary side has a coil 21 and a capacitor 22, with which tuned to the frequency of the subcarrier which carries the difference information of the stereophonic program. Also are still a comparison capacitor or sampling capacitor 25a and a pair of peak detectors are provided, those connected with opposite polarity to a connection point of the comparison capacitor and this capacitor with the opposite connections of the input circuit 21, 22 connect. Although triodes are also used as blocking peak detectors can use, it is common to use the diode detectors shown. One the cathode of these diodes 26a is connected to the high-voltage terminal of the comparative capacitor 25a connected, while the other diode 27 a with its anode to this terminal of the comparative capacitor connected. The anode of the diode 26 a is connected to a terminal of the input circuit 21, 22. The cathode of the diode 27 a is via a time constant element with the resistor 28 a and a capacitor 29 a connected to the opposite terminal of the input circuit. The time constant of the network 28 a, 29 a is large compared to the period of the subcarrier frequency, so that the diode only during the peak value of the regenerated subcarrier signal for control or switching purposes becomes conductive in a manner to be described later.

So that the comparison capacitor 25 a can derive the A signal directly from the multiplex signal from the ratio detector 13, an arrangement has been made which is used to charge the comparison capacitor in two directions and consists of a circuit whose time constant is small compared to the time intervals the power line of the peak detectors. One of the charging circuits can lead from the high-voltage terminal of the comparative capacitor 25a via the diode 27a through the time constant element 28α and 29a to a center tap of the band filter coil 21 and from there via a line that leads to the voltage-carrying connection point of a resistor 30, its other Connection point to ground. Since this circuit has a one-sided current-conducting diode 27 α, a circuit for charging the capacitor 25 a is created, which is only current-permeable in one sense. The circuit for charging the capacitor in the opposite sense is essentially the same, with the one exception that it is connected to the high-voltage terminal of the capacitor.

5 6

sators25a does not feed through the diode 27 a, but feeds through, and the deemphasis filter of the ß-channel feeds the diode 26 a. It also represents a circuit that conducts electricity in a corresponding stage of the LF amplifier 45 b and direction, its diode is a loudspeaker 46 b. The loudspeakers are, however, polarized in the opposite way to the diode of the first - the usual spatial arrangement - opposing charging circuit. 5 provides a stereophonic sound reproduction

These charging circuits will deliver through the signal.

opened, which from stage 40 to the input When considering the mode of operation of the Empkreis 21, 22 is given. It is important that it is assumed that the received carrier of this signal has a frequency which corresponds to the frequency of the signal in accordance with the modulation suppressed carrier wave of the modulated auxiliary function of the above equation modulated carrier signal, which is the difference information. If this is the case, then represents the multiplex signal that contains. It is also important that this signal, which at the output circuit of the ratio detector 13 has peak values, which are temporally in phase with the available, represent this modulation function and peak values of the subcarrier signal. This also contains the pilot signal component S '. The phase relationship required for the pilot can be established in a wide variety of signal components from the amplifier 41. By means of an automatic screened, amplified and used to control the stage phase control system, which is on the one hand to 40, so that a regenerated subcarrier entdie stage is coupled and on the other hand speaking signal with the above-described to a pilot signal amplifier 41, which in turn ratio detector 13 is coupled to frequency and phase features in push-pull circuits, the pilot signal can be given to the two detector channels, the output circuit of the ratio detector is removed. At the same time, the multiplex signal is removed from the ratio. The output signal of the stage 40 detector via the cathode follower 31 in push-pull then fulfills all the requirements with regard to activation on these two channels. Each sequence and phase position, as it is on the input circuit pair of diodes 26 a, 27 a and 26 b, 27 b is alternately 21, 22 must be given. 25 selnd conductive in order to obtain the gs-

Of course, it is also necessary to scan the signal supplied and to receive the A and ß audio multiplex signals on the detector signals described above directly and to send them directly to channels. This is achieved with the help of an amplifier 45 a and 45 b to give a circuit through which the multiplex signal is reproduced in the stereophonic program. The push-pull is given to these channels. This 3 ° derivation of the A and β audio signals results in the order is shown here as a cathode follower stage - in detail from the curves in FIG Waveform of the curve C on, its control electrode with the output circuit of while the waveform of the .B signal through the ratio detector 13 via a coupling capacitor curve D is shown. The curve E represents the Multi-32 is connected. Resistor 30 represents the complex signal, the pilot signal contained therein representing method impedance for the cathode follower stage. Additional information has been omitted for the sake of simplification.
in addition to the feed of the multiplex signal into The curve E illustrates the FM multiplex, the detector channels, the cathode follower signal according to term 1 and term 2 of the above-mentioned 31 simultaneously serves to bias a given equation. It represents the amplitude modulus diode of each channel to make this a 40 lated subcarrier signal with suppressed carrier diode current-conducting, if at the output, the superimposed on the sum of the A and B signals of the stage 40 no signal occurs. To that end is. The vertex marked with dots is the control electrode of the cathode follower, also with subcarrier oscillation, represents the ^ 4 signal. As can be seen from a voltage divider from the graphs connected in series, the resistors 33 and 34, which are connected to terminal + B 45 phase position of the subcarrier oscillation at time t _f , to which the anode has also been reversed. This is an essential feature triode 31 is connected to. The bias circuit of the modulation with suppressed carrier wave because can e.g. B. from the voltage-carrying connection in such a modulation method, the eye point of the resistor 30 to the tap on the visible phase of the carrier is reversed in each case. Coil 21 and from there to the anodes of the diode 26 a 50 when the modulated oscillation lead the zero axis and 26 b . The DC circuit that is required. In fact, the phase reversal is borrowed to open the diode, is continued by construction as a result of averaging at a time element, which is a deemphasis or de-point at which the carrier oscillation is removed from the zero point accent filter to equalize the A- and.

β-Audio Signals from Comparison Capacitors 55. One form of the signal received from stage 40. The resistance component of the De- is supplied in order to key the diodes in such a way that the emphasis filter of one channel contains the resistance. Comparison capacitor the peak values of the auxiliary stands 35a and 36a, both of which can follow parallel to the carrier signal, is shown in the curve F are equal capacitor 25 a and thereby set a time. It shows a sequence of uniform constant setting, which is large compared to the 6 ° pulses, whose polarity alternates and which are the time constants for charging the capacitor. have the same frequency as the subcarrier oscillation. This time constant is preferably made so large and also selected with the peak values that the comparison capacitors coincide in time during the subcarrier oscillation. Which the comparison interval cannot discharge. The amplitude of the signal of curve F must be large, and the de-emphasis filter also contains a secondary 65 compared to the maximum amplitude of the multi-circuit capacitor 37a. plex signal from the ratio detector 13 so that it

The de-emphasis filter of channel A leads to an inappropriateness of scaling the signals

LF amplifier 45 a, which reproduces a loudspeaker 46 a in the drawing. The negative

Claims (4)

7 8 Pulses of the signal of curve F switch the diodes. This means that when receiving a mono 26 α and 27 a at the same time. If the diodes phone program only conducts the monophonic signal in this way, then the deemphasis filter is transmitted without change via both detector channels to the upper connection point of the comparison capacitor, from where the voltage of the upper ungrounded connection 5 is transmitted to the amplifier 45 a and 45 b is given. This final point of the cathode resistor 30 of the amplifier now transmit the same signal, and cathode follower on. This has the effect that the monophonic sound reproduction results with the same capacitor receives a charge that represents the external loudspeakers 46 a and 46 δ, each visual potential of the peak value of the auxiliary loudspeakers reproducing the same program signal in phase with io Of course, the receiver of this impulse of the signal of curve F (comparative even on monophonic or stereophonic reproduction signal) is. The voltage drop at the cathode corresponding to the character of the resistance 30 received naturally changes from a signal. When receiving a stereophonic equal interval to the next matched signal, the voltage drop across the cathode will be with the modulation. But since the diodes 26 a and 15 resisted 30, which opens the diodes 26 a and 26 b. 27 a charging current branches for the comparison capacitor through the time constant element 28, 29 of the diode 25 a compensated peak detectors with a small time constant in two directions. open, the charge of the capacitor is regulated.
the converted signal. The dashed line H in Fi g. 2 illustrates the resistor 28 at 220,000 ohms Change in the state of charge of the comparison capacitor resistance 3 © 15,000 ohms sators 25 a over the sequence of comparison intervals. Resistor 33 680 000 ohms This curve has the character of a staircase radio resistance 34 1 megohm tion, because the capacitor is in the interval " _r,. , - _{Λη nnn} γ \ λ, Ί, . ' ,,, r,. , ... ,, ..,. Resistance 35 47 000 ohms between the comparison processes not about eme the diodes 26a or 27a can discharge and the resistance 36 470 000 ohms Time constant of the capacitor in connection with capacitor 22 62,000 micro-microfarads the resistors 35a and 36a as high as possible 30 capacitor 25 .... 2 200 micro-microfarads is. The filtering effect of the de-emphasis filter blurs capacitor 29 0 047 microfarads S Sto ^ h ^ ter the curve # so that in the capacitor 32 .... 0.100 microfarads LF amplifier 45a, the separated ^ 4 signal arrives,., * ™ \> ri ™ · ι * λ which corresponds to curve C. Capacitor 37 .... 1,500 micro-microfarads In the same way, the positive pulses 35 control diode 26 type 1/2 6 AL5 of the signal of curve F the diodes 26 & and 27 b, diode 27 type 1/2 6 AL5 so that they are simultaneously in those intervals Triode31 Type6C4 become conductive that are in the middle between on- c ^ _Q - " _a """"""""π _{± 1!} · Ηυι ₍ j. , j, ' _r,. . . . "J _ .. j supply voltage ß ... +250 volts successive comparison intervals of the diodes * τ α α 26 α and 27 α lie. The intervals of the power line 40 amplitude of the demo or comparison processes caused by the influence of the dulation signal,
of the signal according to curve F to the diodes 26 & from peak to peak and 27 b are given, allow the condensation to be measured at 200 volts sator256, the opposite peak values of the maximum amplitude
Subcarrier to follow to develop the S signal 45 des together. In order to clearly illustrate the comparative effect of the con-set modulator capacitor 25 b , the tion signal is 10 volts Multiplex signal shown again in curve G. The frequency of the Points at the vertices of the auxiliary beam illustration illustrate the comparison points that apply to 50 signals at 38 kHz the capacitor 25 b occur. It goes without saying even that the voltage across the capacitor 25 b represents the β signal; it is determined by the de-emphasis form of the demodulation signal in curve / ⁷ filter equalized and used on the audio amplifier 45 & in the, and you can see this waveform 5-channel given. 55 come very close by means of a pulse generator, In this way, the described arrangement leads the with the help of a pulse converter to the detector the A and S signals immediately from the fact that channels are coupled. In practice it is sufficient they completely exclude the signal output of the ratio detector 13, this signal a sinusoidal one draws, so that no special matrix network and waveform to give whatever, of course, always then the core matrix method is required. 60 is the case when this signal is During the time in which the receiver learns from the pilot signal of the received carrier monophonic transmission, no output wave occurs.
signal of stage 40, since the signal transmitted by the transmitter then carries no pilot frequency. In the claims:
In this case, the DC voltage that is applied to the 65 method resistance 30 of the cathode follower 31 drops, 1. Circuit arrangement for a compatible the diodes 26 a and 26 & of the two detector channels stereo decoder in one with a ratio detector constantly, so that they represent passive resistance. equipped FM receiver to receive Signals that, according to the pilot tone method, consist of a carrier wave directly modulated with the sum of the right and left AF signals, an amplitude-modulated subcarrier with a suppressed carrier wave with the difference between the right and left AF signals, and a carrier wave with the frequency assemble the pilot tone held synchronously of the subcarrier, with a stage for the recovery of the suppressed subcarrier, characterized in that a synchronous detector with a center-tapped transmitter (20) is provided for the subcarrier, on the output side of which the subcarrier occurs in push-pull that the center tapping of the output side of the Transformer is connected to an output of the ratio detector which carries the demodulated LF signals, so that the two ends of the center-tapped winding of the transformer each have time constant elements (28 a, 29 a; 28 b, 29 b) and two diodes connected in the same direction in series (26 a , 27 a; 26 b, 27 b) each with the other The end of the center-tapped winding (21) are connected, that a charging capacitor (25 a, 25 b) is led to ground from the junction of two diodes, at each of which a channel signal arises, that the two diode circuits are connected to the transformer with opposite polarity and that the time constant of the time constant members is large compared to the period of the subcarrier. 2. Circuit arrangement according to claim 1, characterized in that the charging time constants the charging capacitors are small compared to the opening intervals of the diodes. 3. Circuit arrangement according to claim 1 or 2, characterized in that the diode circuits are connected to a transmitter tuned to the subcarrier frequency. 4. Circuit arrangement according to claim 1 to 3, characterized in that the relevant Output of the ratio detector with the center tap of the transformer output side via a Cathode follower is connected. 1 sheet of drawings